Summary
Nanofiltration (NF) and reverse osmosis (RO) membranes are widely and increasingly used for water treatment process.
The efficiency of NF and RO processes is however adversely affected by biofouling. Environmental stimuli can trigger selfcleaning
mechanisms of natural surfaces. Consequently there is an increasing interest in developing smart or stimuli
responsive polymers as coatings to prevent biofouling. However, external chemical/physical stimuli must be selectively
applied to the smart polymers to induce the cleaning mechanism; this procedure limits their applicability at industrial scale.
The unique idea of this Proof of Concepts is to develop smart polymeric surfaces that, triggered by chemical (enzymatic)
stimuli induced by biofouling, will exploit the self-cleaning mechanism. This concept is expected to dramatically reduce the
operating costs of NF and reverse osmosis RO processes. Bio-stimulated smart polymers surfaces will be incorporated into
NF/RO feed spacers which are integral to the spiral wound configuration used in full scale membrane treatment plants. The
commercialisation route of the product will be through the patent protection and the licensing of the technology with a view to
rapid commercialisation.
The efficiency of NF and RO processes is however adversely affected by biofouling. Environmental stimuli can trigger selfcleaning
mechanisms of natural surfaces. Consequently there is an increasing interest in developing smart or stimuli
responsive polymers as coatings to prevent biofouling. However, external chemical/physical stimuli must be selectively
applied to the smart polymers to induce the cleaning mechanism; this procedure limits their applicability at industrial scale.
The unique idea of this Proof of Concepts is to develop smart polymeric surfaces that, triggered by chemical (enzymatic)
stimuli induced by biofouling, will exploit the self-cleaning mechanism. This concept is expected to dramatically reduce the
operating costs of NF and reverse osmosis RO processes. Bio-stimulated smart polymers surfaces will be incorporated into
NF/RO feed spacers which are integral to the spiral wound configuration used in full scale membrane treatment plants. The
commercialisation route of the product will be through the patent protection and the licensing of the technology with a view to
rapid commercialisation.
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More information & hyperlinks
| Web resources: | https://cordis.europa.eu/project/id/640492 |
| Start date: | 01-02-2015 |
| End date: | 31-07-2016 |
| Total budget - Public funding: | 149 909,68 Euro - 149 909,00 Euro |
Cordis data
Original description
Nanofiltration (NF) and reverse osmosis (RO) membranes are widely and increasingly used for water treatment process.The efficiency of NF and RO processes is however adversely affected by biofouling. Environmental stimuli can trigger selfcleaning
mechanisms of natural surfaces. Consequently there is an increasing interest in developing smart or stimuli
responsive polymers as coatings to prevent biofouling. However, external chemical/physical stimuli must be selectively
applied to the smart polymers to induce the cleaning mechanism; this procedure limits their applicability at industrial scale.
The unique idea of this Proof of Concepts is to develop smart polymeric surfaces that, triggered by chemical (enzymatic)
stimuli induced by biofouling, will exploit the self-cleaning mechanism. This concept is expected to dramatically reduce the
operating costs of NF and reverse osmosis RO processes. Bio-stimulated smart polymers surfaces will be incorporated into
NF/RO feed spacers which are integral to the spiral wound configuration used in full scale membrane treatment plants. The
commercialisation route of the product will be through the patent protection and the licensing of the technology with a view to
rapid commercialisation.
Status
CLOSEDCall topic
ERC-PoC-2014Update Date
27-04-2024
Geographical location(s)
